Having access to live data from out in the field is incredibly valuable in making smart, informed decisions about your business. Fleet vehicle and other traveling asset operations benefit greatly from an in-vehicle data logging and tracking solution. The challenge is collecting and sharing this data reliably because of the inherent challenges with a mobile solution. For example, there are additional power supply considerations for a vehicle that is always starting and stopping. When power is unexpectedly cut off from the embedded data logger, there is a high likelihood of filesystem and data corruption. Another consideration is how to transfer the data once you’ve captured it via CAN or GPS. Thankfully, cellular network providers have done a great job at providing an always-available, nationwide service accessible from nearly anywhere. It would make sense to tap into this network using a cellular modem. Then, perhaps when the vehicle returns to a base station, WiFi or Bluetooth connections can be used to share auxiliary, non-real time data. Lastly, you’ll want to consider operating temperature ranges, as the inside a vehicle can easily reach 130 ºF to 170 ºF (54 ºC to 76 ºC) and on the opposite, reach “Ice Road Truckers” cold to -50 ºF (-45 ºC). It’s important to keep these considerations of power, temperature, and connectivity in mind in order to keep all this data safe and sound. The TS-7670 and TS-7680 single board computers are embedded systems which aim to provide reliable, low power, industrial-grade vehicle asset tracking solutions and solve these challenges.
This guide will walk you through the basic steps of getting your TS-TPC-8390-4900 touch panel computer (TPC) up and running. It’s mostly an extrapolation from the official TS-TPC-8390-4900 Manual, but provides a more practical approach in setting up common connections, networking, and environments to begin development. We’ll assume you’ve already gone through the excitement of unboxing, and we’ll pick up from there.
Let’s get our TS-TPC-8390-4900 hooked up! This includes our very basic connections we’ll need for most any development or project: power, serial console, Ethernet, and optionally a keyboard and mouse.
Quality conscience project managers and engineers understand that when looking for a solutions provider, quality certifications are vitally important. Top of mind certifications, like ISO-9001, ensure reliable manufacturing, processing, and testing of end products before they’re packaged up and shipped out the door. In the embedded systems and electronics world, there is another quality certification called IPC-A-610 which is an international source for end product acceptance criteria for high reliability electronic components. This certification allows quality conscience decision makers to rest easy with their choice of embedded systems supplier knowing that all IPC-A-610 certified technicians and production employees are trained not only to spot and correct any physical defects, but also how to handle the end product to maximize life and dependability in the field.
IPC-A-610 holds manufacturing technicians to a higher standard for testing and inspection. These trained Certified IPC Specialists (CIS) possess the knowledge to identify defects which could cause latent or immediate malfunction. Examples of such defects include:
- A missed cold solder joint (pictured) could cause a latent power failure in the field due to the solder bond cracking.
- Cracked components, which pass initial inspection, break under the forces experienced in the shipping and receiving process.
- Loose solder balls that when dislodged, can cause a short between traces on the PCB board and result in damaging sensitive components and board failure.
All CIS are trained to carefully detect all of these issues, among others, to ensure the embedded system performs reliably in the field. On top of spotting and correcting any physical defects, they are also trained to be careful when handling the boards to maximize the life of the board in the field. This is important, since a small percentage of a boards life is diminished every time a soldering iron or non-ESD protected person touches it. CIS understand that even oils and salts from their fingers can contaminate the board, causing latent issues.
There are three classification standards for the accept/reject criteria defined by IPC: Class 1 being general electronic products where the only requirement is to function, Class 2 being dedicated service electronic products where continued performance and extended life is required as well as uninterrupted service is not critical but desired, and Class 3 being high performance/harsh environment electronic products where continued high performance or performance-on-demand is critical to the working end product and must not fail, such as a life support machine at a hospital. All CIS are trained for all three of these classifications for the utmost quality assurance.
Highly reliable embedded system deployments start with choosing a partner who not only carries certifications for manufacturing, process, and designing through ISO-9001, but also employs highly trained, IPC-A-610 certified technicians and production personnel to ensure proper handling and repair throughout the entire process.
Here at Technologic Systems, we pride ourselves in our product quality, ensuring our customers get the highest quality end product. Our entire production team is not only IPC-A-610 certified, they are passionate about quality, keeping up to speed on new quality standards to ensure top level performance and life out of our products. We take extensive care in making sure that the product is carefully handled and meets the highest acceptance criteria so that our customers will be getting what they deserve.
“IPC training has given me greater knowledge and understanding of what can cause a latent problem on boards in the near or distant future. Before going to training I would say that you could consider me to be meticulous with the quality of the product I am working with. But I didn’t realize that even something as small as the oils on my hands can cause latent problems for the board. I also learned that there is a long-term cost to making repairs so that on components with metalization loss it’s actually better not to repair it if the loss is still within the acceptable range.” — Camron Vogelzang, Repair Technician
Simple Embedded Monitor and Control Dashboard
Here’s an example program our engineers might find useful. Jesse Off, our lead engineer, wrote this simple program to get the voltage input (Vin) on the 8 – 28 VDC power rail on the TS-7250-V2 (Rev. B only). Without going into too much detail about implementation of the SiLabs microcontroller, there is a register which is used to store various ADC values, including Vin. This example program basically polls this 19 byte register via I2C interface, accounts for the voltage divider (see TS-7250-V2 schematic), and spits out the Vin value. So, without further ado, here’s the code:
This guide will walk you through the basic steps of getting your TS-7250-V2 up and running. It’s mostly an extrapolation from the official TS-7250-V2 Manual, but provides a more practical approach in setting up common connections, networking, and environments to begin development.
Let’s get our TS-7250-V2 hooked up! This includes our very basic connections we’ll need for most any development or project: power, serial console, and Ethernet.
While home automation first put the Internet of Things concept into the technology mainstream, industrial IoT is where this nascent high-tech sector’s growth truly lies. Companies of all sizes, spanning many different industries, hope to gain a competitive advantage using a variety of IoT applications.
A typical industrial IoT scenario involves data from sensors embedded inside equipment that communicates with a small gateway computer connected to the Internet. A remote data analyst or engineer uses this information in a myriad of ways. The ultimate goal of the application could be optimizing performance by detecting either hardware breakdowns or simply inefficient operation.
Frankly, this is only one of many different possibilities. Let’s dive into some reasons why the time for industrial IoT is today.
The TS-ADC24 can provide up to 8 MB/s of ADC data, but the ISA (PC/104) bus on most systems is limited to 2 MB/s bandwidth or less. So one might conclude that the TS-ADC24 is over-designed. However, the TS-ADC24 itself does not require the long ISA strobe times that typical PC/104 systems use, and a well-designed PC/104 system such as the TS-8100-4740 featuring a Spartan 6 FPGA can actually exceed 2MB/s for sustained bursts. This translates into sampling 4 ADC channels at 250 kHz or even 500 kHz. This is possible due to standard functionality in the FPGA including customizable bus timing, user DMA, and an embedded processor. With extra engineering, 1000 kHz would be possible, but this article explores what can be accomplished by a typical C programmer who does not want to venture into the realm of FPGA development.
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